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Articleshttps://doi.org/10.1038/s41565-019-0478-y
1Department of Chemistry and Chemical Biology, Harvard
University, Cambridge, MA, USA. 2Advanced Technology Institute,
University of Surrey, Guildford, Surrey, UK. 3Center for
Nanomedicine, Institute for Basic Science (IBS), Yonsei-IBS
Institute, Yonsei University, Seoul, Republic of Korea. 4Center for
Brain Science, Harvard University, Cambridge, MA, USA. 5John A.
Paulson School of Engineering and Applied Sciences, Harvard
University, Cambridge, MA, USA. 6These authors contributed equally:
Yunlong Zhao, Siheng Sean You, Anqi Zhang *e-mail:
[email protected]
Developing new tools that enable reproducible high
spatial–temporal resolution recording of intracellular potential,
while maintaining the capability for device scalability, are key
goals for advancing electrophysiology studies of electrogenic cells
and cell networks1–4. Patch-clamp electrodes have been the gold
stan-dard for cell electrophysiology for decades, and they have
shown that accurate recording of the intracellular potential
requires a high-resistance seal against the cell membrane and low
resistance between the recording element and the cell interior5,6.
Recent stud-ies have focused on several solid-state nanodevice
architectures, including nanowire-based structures for optical
neuronal stimula-tion7,8, scalable on-chip micro/nano-structured
electrode arrays9,10 for attenuated intracellular recording via
electroporation11,12 and/or optoporation13,14, and
three-dimensional (3D) nanowire field-effect transistor probes for
intracellular recording of single cells15,16. Nanowire probes have
recorded cardiac intracellular action poten-tials with amplitudes
comparable to those recorded with patch-clamp micropipettes15,16,
but have relied on one-by-one fabrication that has been difficult
to scale up. For solid-state nanoprobes to achieve comparable
recording signal-to-noise ratio and ampli-tude to those of patch
clamp measurements, the nanodevice must achieve direct contact of
the recording element with the intracel-lular solution without
significantly disturbing the cell membrane2,9. Fulfilling these
criteria requires understanding the size, geometry and mechanical
and biochemical factors present at the cell mem-brane–nanodevice
interface. Recent work suggests that nanoscale size and geometry
play a key role in the interaction between the nanostructure and
the cell membrane17,18. For example, nanoscale membrane curvature
elevates the local concentration of endocyto-sis-related
proteins17,18, influences the conformation and activity of
transmembrane proteins19 and is hypothesized to recruit a sequence
of proteins leading to membrane fission20. Building on these
stud-ies, we hypothesize that inducing appropriate nanoscale
curvature
on the cell membrane via rational device design will facilitate
probe internalization and enable intracellular recording.
Here, we investigate how the size and geometry of nano-probes
influence intracellular recording by fabricating scalable 3D
U-shaped nanowire field-effect transistor (U-NWFET) arrays in which
both the radii of curvature (ROC) and active sensor sizes are
controlled (Fig. 1a). To investigate how these design factors
affect electrophysiological recording, arrays of U-NWFET probes
fabri-cated from 15-nm-diameter p-type Si nanowires with ROC from
0.75 to 2 μm and active channel lengths from 50 to 2,000 nm were
used to probe cultured primary neurons and human cardiomyo-cytes.
Schematically, we ask whether probes with the smallest ROC and
sensor size (Fig. 1b(i)) can facilitate recording full amplitude
intracellular action potentials and subthreshold features, where
increases in the ROC and detector sizes (Fig. 1b(ii)) would lead to
recording smaller amplitude intracellular-like or extracellular
action potential peaks.
U-shaped nanowire probe fabrication and characterizationOur
strategy for producing reproducible arrays of U-NWFET probes with
controlled ROC and active FET channel lengths or detector sizes
involves two key techniques (see Methods for details). First,
large-scale, shape-controlled deterministic assembly21 is used to
produce U-shaped nanowire arrays from 15-nm-diameter Si nanowires
with controllable ROC on top of Si3N4 patterns (Fig. 2a(i) and
Supplementary Fig. 1a–e). Metal contacts are then deposited and
passivated by an upper Si3N4 layer (Supplementary Fig. 1f). Second,
we exploit spatially defined solid-state transforma-tion22 to
convert Si nanowire segments underneath and adjacent to the Ni
diffusion layer to metallic NiSi, thereby producing a con-trolled
length of FET sensing elements at the tips of the U-shaped nanowire
probes (Fig. 2a(ii) and Supplementary Fig. 1g). Finally, etching of
the sacrificial layer allows the probes to bend upward
Scalable ultrasmall three-dimensional nanowire transistor probes
for intracellular recordingYunlong Zhao 1,2,6, Siheng Sean You
1,6, Anqi Zhang1,6, Jae-Hyun Lee1,3, Jinlin Huang1 and Charles M.
Lieber 1,4,5*
New tools for intracellular electrophysiology that push the
limits of spatiotemporal resolution while reducing invasiveness
could provide a deeper understanding of electrogenic cells and
their networks in tissues, and push progress towards human–machine
interfaces. Although significant advances have been made in
developing nanodevices for intracellular probes, current approaches
exhibit a trade-off between device scalability and recording
amplitude. We address this challenge by combining deterministic
shape-controlled nanowire transfer with spatially defined
semiconductor-to-metal transformation to realize scal-able nanowire
field-effect transistor probe arrays with controllable tip geometry
and sensor size, which enable recording of up to 100 mV
intracellular action potentials from primary neurons. Systematic
studies on neurons and cardiomyocytes show that controlling device
curvature and sensor size is critical for achieving high-amplitude
intracellular recordings. In addition, this device design allows
for multiplexed recording from single cells and cell networks and
could enable future investigations of dynamics in the brain and
other tissues.
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due to interfacial strain in the metal interconnects (Fig.
2a(iii))15, yielding probe arrays with up to four addressable
U-NWFETs per bend-up probe arm (Supplementary Fig. 1h).
Optical microscopy and scanning electron microscopy (SEM) were
used to characterize key steps in the U-NWFET probe fab-rication
flow. Optical microscopy images of the patterned bottom passivation
layer and U-shaped trenches that set the ROC during nanowire
assembly (Supplementary Fig. 2a,b) as well as three probes with
U-shaped nanowires, metal contacts and top passivation layer (Fig.
2b) are indicative of the deterministic parallel assembly of
U-shaped nanowire probes with defined ROC. Composition-sensitive
SEM images of U-NWFETs following annealing of the patterned Ni
further highlight the control of channel lengths from ~50 nm (Fig.
2c) to 500 and 2,000 nm (Supplementary Fig. 2c,d). Measured channel
lengths and ROCs were found to be consistent with those designed
(Supplementary Fig. 3). Etching of the Ni release layer produces
arrays of probes, including single U-NWFET probes (Fig. 2d) and
multiple U-NWFET devices on a single probe arm (Supplementary Fig.
2e) where the active U-NWFET sensor elements are oriented upwards
away from the substrate.
Electrical transport studies in air and aqueous solution were
carried out to characterize the sensor properties. Current versus
drain–source voltage (I–Vds) measurements on devices with chan-nel
lengths of ~50, 500 and 2,000 nm (Fig. 2e–g; N = 10, each chan-nel
length) in the dry state yield average conductances of 3.3 ± 0.6,
0.7 ± 0.2 and 0.3 ± 0.1 μS, respectively. In addition, conductance
versus water gate voltage (Vg) measurements in aqueous solution
(Fig. 2h–j) yield average transconductances of 5.4 ± 1.3, 2.3 ± 0.7
and 0.9 ± 0.3 μS V−1 for 50, 500 and 2,000 nm channel lengths,
respectively. Plots of probe transconductance versus ROC (0.75–2.0
μm) for devices with 50, 500 or 2,000 nm FET channels
(Supplementary Fig. 4 and Supplementary Table 1) show that
trans-conductance does not significantly vary as a function of ROC
in our designed strain range (Supplementary Table 2). The
conductance and transconductance results for the U-NWFETs are
roughly con-sistent with the expected inverse relationship to the
channel length. Finally, the transconductance and measured noise
values yield an estimate for signal detection sensitivity (three
standard deviations) of 0.90 ± 0.60, 1.2 ± 0.9 and 1.9 ± 0.9 mV for
50, 500 and 2,000 nm channel lengths, respectively, which should
allow detection of the typical 1–10 mV subthreshold activities of
neurons2.
Near full amplitude intracellular recordingsWith these
characterization results, we first asked whether ultrasmall U-NWFET
probes could record full amplitude intracellular action potentials
from primary neurons. First, a single U-NWFET probe with ~50 nm FET
length and 0.75 μm ROC was used to sequen-tially measure six
independent dorsal root ganglion (DRG) neu-rons (see Methods and
Supplementary Fig. 5), where the probe was not remodified with
lipid between the sequential measurements (Supplementary Fig. 6).
In each trace, we observe a drop in the baseline potential upon
initial cell contact (Fig. 3a). Subsequently, either sparse peaks
(cells 1, 3 and 6) or periodic peaks (cells 2, 4 and 5) are
observed with amplitude of 60–100 mV and signal-to-noise ratios of
115 ± 29. For each cell, the recorded potentials have con-sistent
shape and duration, and characteristic single peaks recorded from
the six cells are shown in Fig. 3b. An additional set of data
recorded from two DRG neurons without spontaneous firing
prop-erties showed a voltage drop (Supplementary Fig. 7a), or one
single peak followed by a voltage drop (Supplementary Fig. 7b),
during device penetration. Following the initial recording, we
observed a gradual decrease in the peak amplitude as well as a
positive shift in the baseline potential (Fig. 3c,d and
Supplementary Fig. 7).
These recordings highlight several key features. First, the
wave-forms, amplitudes, firing patterns and signal-to-noise ratios
of the peaks are similar to our patch-clamp recordings of similarly
cul-tured DRG neurons (Supplementary Fig. 8) and are consistent
with the reported heterogeneity of spontaneously firing DRG action
potential waveforms and spike patterns23. These data thus indi-cate
that the ultrasmall U-NWFETs with biomimetic phospholipid
modification can provide high-resistance membrane seals, achieve
direct access to the cell interior, and yield faithful recording of
the intracellular potential. Notably, the data recorded from some
DRG neurons exhibit characteristics consistent with
mechanosensitive properties24, including an increase in action
potential firing rate (Fig. 3c,d) and firing of a single action
potential (Supplementary Fig. 7b) during formation of the
device/cell junction. A limitation of the recording is, however,
the shift in baseline and decrease in recorded action potential
amplitude at later times (for example, Fig. 3c). We suggest that
these changes are due to either an elastic response from the
cytoskeleton, which gradually pushes the probe out of the cell as
suggested in other intracellular chemical delivery experiments25,
or mechanical instability of the measurement set-up.
a
Cytoplasm
FET
Cytoplasm
Extracellularfluid
FET
Conductingnickel silicide
Conductingnickel silicide
b
i ii
Fig. 1 | Ultrasmall U-NWFet probe as a new approach for
electrophysiology. a, Schematics of intracellular recording by a
U-NWFET probe. The location, size, geometry of each probe and the
sensor size can be well modulated by a deterministic
shape-controlled nanowire transfer technique and spatially defined
transformation of Si nanowire segments to NiSi, respectively. b,
Schematics of two possible probe–cell interfaces. (i)
Internalization and high-resistance seal of a short-channel U-NWFET
to the cell membrane enables high-amplitude recording. The
sensitive p-type Si NWFET region and the metallic NiSi region on
the U-shaped nanowire are marked with red and blue-grey,
respectively. The nanowire is shown modified with phospholipid.
(ii) Partial sealing/internalization of the U-NWFET with longer
channel length/ROC results in attenuated intracellular-like action
potential recording.
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Given the high signal-to-noise ratio for our measurements, we
asked whether it was possible to observe subthreshold activ-ity.
Notably, close examination of a representative trace from a
cell
with irregular firing pattern (Fig. 3d) shows subthreshold
features, including a single ~5 mV peak (Fig. 3e(i)) and a series
of three small peaks (Fig. 3e(iii)) immediately before the
initiation of an action
–0.10 –0.05 0.00 0.05 0.10
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Fig. 2 | Fabrication and characterization of U-NWFet probes. a,
Schematics of device fabrication. (i) Assembly of U-shaped nanowire
devices on a Ni sacrificial layer and bottom Si3N4 passivation
layer; electrical contacts to the transferred U-shaped nanowires
are made via deposition of Cr/Au/Cr (1.5/60/60 nm) metal
interconnects, where the relative Cr/Au/Cr thicknesses yield a
built-in strain that bends the probe up upon release. (ii)
Deposition of the top Si3N4 passivation layer and the Ni diffusion
layer followed by rapid thermal annealing to transform the Si
nanowire segments underneath and adjacent to the Ni diffusion layer
to NiSi, thus generating a local FET at the tip of the U-shaped
nanowire. (iii) Probes bending upward after etching the Ni
diffusion and sacrificial layers. b, Optical image of three devices
following deposition of metal interconnects and before deposition
of the nickel diffusion layer. Inset, magnified view showing that a
U-shaped nanowire is deterministically transferred to the device
tip. Scale bar, 20 μm. c, SEM image of the device after Ni
diffusion. Scale bar, 500 nm. Inset, magnified SEM image of the
dashed region showing the resulting local FET at the U-shaped
nanowire tip. Imaging with backscattered electrons (BSE) shows the
Si (dark region) and NiSi (bright region) distribution on the
U-shaped nanowire. Scale bar, 50 nm. d, Optical image of the
bend-up device array in water. Scale bar, 20 μm. e–g, Current
versus drain–source voltage (Vds) traces for 10 devices in the dry
state for ~50 nm (e), ~500 nm (f) and ~2,000 nm (g) channel
lengths. Insets, SEM images taken using the BSE mode of the local
FET following removal of the Ni layer. Scale bars, 50 nm (e),
0.5 μm (f), 0.5 μm (g). h–j, Left, conductance versus reference
water gate potential (Vg) recorded from one representative device
for each channel length (~50 nm (h), ~500 nm (i) and ~2,000 nm (j))
in Tyrode’s solution. Right, box and whisker plots showing the
distribution (N = 10) of transconductance for devices of each
channel length gated by a reference electrode in Tyrode’s solution.
The blue triangle shows the mean of the transconductances, the top
and bottom edges of the box indicate the upper/lower quartiles and
the whiskers indicate the highest and lowest measured values,
respectively.
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potential, as well as an ~3 mV peak not associated with an
action potential spike (Fig. 3e(ii)); we recorded similar results
with patch-clamp (blue triangles, Supplementary Fig. 8). Previous
multi-patch-clamp studies have reported comparable subthreshold
signals and attributed them to excitatory postsynaptic potentials
in which a pre-synaptic cell triggers the firing of the
postsynaptic cell2,26. This sug-gests that our U-NWFET devices can
measure biologically relevant subthreshold signals and could be
used for future studies of neural connections and synaptic
activity.
After achieving neuronal intracellular recording, we asked
whether the U-NWFET probes could be generalized to other
electrogenic cells. To answer this, we cultured human induced
pluripotent stem cell-derived cardiomyocytes (HiPSC-CMs) (see
Methods). Contact of a HiPSC-CM and a U-NWFET probe of ~50 nm FET
length and 0.75 μm ROC (Supplementary Fig. 9a,b) initially yielded
a ~25 mV drop in the baseline, followed by periodic
~50 mV positive waveforms with a sharp rising phase (
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For DRG neurons, representative intracellular/intracellular-like
record ings were obtained by probes with 1 μm and 1.5 μm ROC (Fig.
4b,c), showing maximum action potential amplitudes of
~35 mV and ~12 mV, respectively. The distribution of maximum
recording amplitudes from both cell types (Fig. 4d,e) shows the
average values for DRG/HiPSC-CM cells and number of successful
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8
0 1 2 3 4 5 6 7 8 0 1 2 3 4 5 6 7 8
0 0.2 0.4 0.6 0.8 1.0 1.2
0.66 0.67 0.68 0.69 0.70 0.71 0.72
5 mV
10 ms5 mV
DRG neuronDRG neuron
10 mV
0.70 0.71 0.72 0.73 0.74 0.75 0.76
20 mV
10 ms
Time (s)Time (s)
h
1 mV
Time (s)
4.84 4.85 4.86 4.87 4.88
2 mV5 ms
HiPSC-CM, extracellular HiPSC-CM, intracellular
20 mV
a
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Max
. spi
ke a
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itude
(m
V)
c
h
i ii
Fig. 4 | effect of size and geometry of U-NWFet probes on
electrophysiological recordings. a, Optical image of U-NWFET probes
with different ROC before deposition of a Ni diffusion layer of
0.75 μm (i), 1 μm (ii), 1.5 μm (iii) and 2 μm (iv). Scale bars,
2 μm. b,c, Intracellular/intracellular-like recording from a DRG
neuron by a ~50 nm FET channel length probe with 1 μm (b) and
1.5 μm (c) ROC. Insets, magnified views of selected action
potentials. d,e, Plot of maximum recorded spike amplitude of
recorded action potentials from DRG neurons (d) and HiPSC-CMs (e)
versus ROC with fixed ~50 nm FET length. Coloured bars indicate the
maximum spike amplitudes measured in the given dataset. The
statistical significances were obtained by comparing the datasets
below the ends of the black line using Student’s t-test. *P
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recordings (out of ~30 measurements) of 34 ± 30 (N = 24)/34 ± 14
(N = 31), 19 ± 15 (N = 25)/31 ± 9 (N = 6) and 16 ± 7 (N = 2)/21 ± 9
(N = 7) mV for 0.75, 1.0 and 1.5 μm ROC, respectively.
Interestingly,
the 2.0 μm ROC probes did not yield successful recordings on
either cell type, indicating that increasing ROC correlates with
lower recorded maximum amplitudes. Measurement of device
trans-conductance (Supplementary Fig. 11) and SEM images
(Supple-mentary Fig. 12) indicate that device characteristics do
not change following measurement.
Second, we studied how sensor size affects recording by
fabricat-ing U-NWFETs with channel lengths of 500 nm and 0.75 µm
ROC (Supplementary Fig. 10). Measurements made on both DRG neu-rons
and HiPSC-CMs showed 8 ± 8 (N = 7) and 23 ± 13 mV (N = 10) maximum
intracellular action potential amplitudes, respectively (Fig. 4f).
Furthermore, U-NWFETs with channel lengths of ~2,000 nm and ROC of
either 1.0 µm or 1.5 µm yielded maxi-mum amplitudes of 21 ± 12 mV
(N = 5, blue circles) and 8.0 mV (N = 1, yellow circle),
respectively (Fig. 4g). Some of the 1.5 µm ROC, 2,000 nm channel
U-NWFETs recorded negative spikes with maximum amplitudes of 4 ± 1
mV (N = 4, red triangles), while no successful recordings were
achieved on DRG cells with 2,000 nm channel probes. A
representative trace showing negative spikes from a HiPSC-CM (Fig.
4h) highlights their periodic negative short 0.05) in recording
duration with ROC (Supplementary Fig. 13 and Supplementary Table
4). Additionally, we observed that increasing the channel lengths
showed no difference in recording duration in the DRG cells (P >
0.05), while for the HiPSC-CMs channel length increasing from 50 to
500 nm for the 0.75 µm ROC and from 50 to 2,000 nm for the 1.0 µm
ROC U-NWFET resulted in a statistically significant (P = 0.007 and
0.027, respectively) increase in recording duration (Supplementary
Fig. 13 and Supplementary Table 4). The lack of correlation between
ROC and recording dis-tribution suggests that loss of intracellular
access is related to cur-vature-independent factors. We attribute
the observed increase in recording duration for longer channel
length measurements on HiPSC-CMs to the higher probability of
maintaining a partially internalized configuration during cell
contraction-induced insta-bilities. Recordings obtained on DRG
neurons have shorter dura-tion than HiPSC-CMs, possibly reflecting
the reported differences in cell membrane mechanical properties as
neuron membranes are generally less fluidic than those of cardiac
cells30.
We further ask whether deterministic fabrication with size and
geometry control could enable multisite intracellular record-ing
within a single cell using two U-NWFETs on one probe arm, recording
from cell networks using independent U-NWFET probes, and/or
simultaneous measurement of intracellular/extracel-lular action
potentials from a single cell by two U-NWFETs with different ROC
and channel lengths (Fig. 5a). First, a single DRG neuron soma was
brought into contact with a pair of U-NWFETs
1.6 1.8 2.0 2.2 2.4
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Fig. 5 | Multiplexed electrophysiological recording by U-NWFet
probes. a, Schematics of simultaneous multisite intracellular
recording from a single neuron by paired U-NWFETs on one probe arm
(i), multiplexed intracellular recording from different cells by
U-NWFETs on different probe arms (ii) and simultaneous
intracellular/extracellular recording from one cell by paired
U-NWFETs on one probe arm (iii). b, Simultaneous intracellular
recording from one DRG neuron by two ~50 nm FETs with 0.75 μm ROC
on one probe arm with a 2 μm separation (i); derivative of traces
in the region marked by a dashed box (ii). The vertical dashed
guiding line in ii indicates the time point of the first action
potential. No time delay is observed. c, Multiplexed intracellular
recording from two HiPSC-CMs by one paired U-NWFET probe (i) and
one single U-NWFET probe (ii); derivative of the marked region
(iii). The two probes arms are fabricated with a distance of 350 μm
between them. d, Simultaneous intracellular/extracellular recording
from one HiPSC-CM by one ~50 nm FET with 0.75 μm ROC (top red
trace, original intracellular signal; bottom red trace, derivative
of intracellular signal) (i) and one ~2,000 nm FET with 1.5 μm ROC
on one probe arm with 2 μm separation (ii). (iii) Closer
examination of the marked region.
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0.75 μm ROC) separated by 2 μm on one probe arm. The simultaneously
recorded intracellular action potential amplitudes (Fig. 5b(i))
exhibited values of 46 and 28 mV from the two U-NWFETs. The
derivative of two action potentials signals (Fig. 5b(ii)) and
overlay of the two traces scaled to the same peak amplitudes
(Supplementary Fig. 14a,b) shows that the peaks coincide with each
other, indicating there is no discern-ible delay or waveform
difference observed in the soma between the two channels.
Second, a layer of cultured HiPSC-CMs was brought into con-tact
with paired U-NWFETs on the same probe arm (2 µm separa-tion) and a
third single U-NWFET probe separated by 350 µm from the paired
probe (all three U-NWFETs with ~50 nm channel and 0.75 μm ROC). The
paired probe recorded the intracellular action potential within one
cell with action potential amplitudes of 54 mV and 47 mV (Fig.
5c(i)) in the two channels, while the third probe simultaneously
recorded from another cell with an amplitude of 62 mV (Fig.
5c(ii)). Comparison of the time derivatives (Fig. 5c(iii)) showed
no discernible delay in the paired channels, while there was ~6 ms
delay between paired and single probes. This delay time and probe
separation yield a signal propagation speed of ~5.8 cm s−1, which
agrees with that reported in the literature31. An overlay of the
action potentials (Supplementary Fig. 14c,d) shows good agreement
in the rising phase, and small deviations in the repolarization
phase that can be attributed to different changes in the two
U-NWFET/cell junctions as a result of mechanical contraction32.
Third, paired U-NWFETs containing one ~50 nm FET with 0.75 μm
ROC and one ~2,000 nm FET with 1.5 μm ROC on a single probe arm
with 2 μm separation were fabricated and brought into contact with
a HiPSC-CM (Fig. 5d). The channel with the ~0.75 µm ROC and 50 nm
FET measured waveforms of ~50 mV character-istic of intracellular
cardiac action potentials (Fig. 5d(i)), while the channel with the
2.0 µm ROC and ~2,000 nm FET measured sharp downward spikes of ~2
mV and
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AcknowledgementsC.M.L. acknowledges support from the Air Force
Office of Scientific Research (FA9550-14-1-0136). S.S.Y.
acknowledges an NSF Graduate Research Fellowship. This work was
performed in part at the Center for Nanoscale Systems (CNS) of
Harvard University.
Author contributionsY.Z., S.S.Y. and C.M.L. conceived and
designed the experiments. Y.Z., S.S.Y. and A.Z. performed the
experiments and analysed the data. Y.Z., S.S.Y., A.Z. and C.M.L.
co-wrote the paper. All authors discussed the results and commented
on the manuscript.
Competing interestsThe authors declare no competing
interests.
Additional informationSupplementary information is available for
this paper at https://doi.org/10.1038/s41565-019-0478-y.
Reprints and permissions information is available at
www.nature.com/reprints.
Correspondence and requests for materials should be addressed to
C.M.L.
Journal peer review information: Nature Nanotechnology thanks
Bozhi Tian, Bruce Wheeler and other anonymous reviewer(s) for their
contribution to the peer review of this work.
Publisher’s note: Springer Nature remains neutral with regard to
jurisdictional claims in published maps and institutional
affiliations.
© The Author(s), under exclusive licence to Springer Nature
Limited 2019
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ArticlesNature NaNotechNologyMethodsNanowire synthesis. Si
nanowires (p-type, 15 nm diameter) were synthesized using a gold
nanocluster-catalysed vapour–liquid–solid growth method21. Growth
substrates (15 × 60 mm2 pieces of Si wafer with 600 nm thermal
oxide, Nova Electronic Materials) were oxygen plasma cleaned (100
W, 2 min, 50 cubic centimetres per minute (s.c.c.m.) O2, PJ Plasma
Surface Treatment System), treated with poly-l-lysine solution
(0.1%, 150,000–300,000 g mol−1, Ted Pella) for 5 min, rinsed
thoroughly with deionized (DI) water and dried with nitrogen. Then,
1 ml of aqueous solution of 10 nm gold nanoparticles (Ted Pella)
with a concentration of 1.9 × 1012 particles per ml was dispersed38
on the substrate for 2 min followed by thorough rinsing with DI
water and drying with nitrogen (gold nanoparticle surface
concentration, 0.01–0.04 particles per μm2). The substrate was then
placed into a home-built chemical vapour deposition reactor and the
system was evacuated to a base pressure of 0.6 mtorr. Nanowires
were synthesized at 430 °C at a total pressure of 40 torr with gas
flow rates of 2.5 s.c.c.m. silane (SiH4, 99.9999%, Voltaix) as the
silicon reactant, 3.1 s.c.c.m. diborane (B2H6, 100 ppm in H2,
Voltaix) as the p-type dopant, and 60 s.c.c.m. hydrogen (H2,
99.999%, Matheson) as the carrier gas. Typical growth times of 1 h
yielded nanowires with average lengths of ~50 µm.
U-NWFET probe array fabrication. Key steps involved in the
fabrication of U-NWFET probe arrays are shown in Fig. 2 and
Supplementary Fig. 1, with the key parameters as follows:
(1) LOR 3A (Microchem) and diluted S1805 (S1805: Thinner-P = 1:2
(vol:vol), Microchem) were spin-coated on a Si3N4/SiO2-coated Si
wafer (200 nm Si3N4, 100 nm SiO2 on p-type Si, 0.005 Ω cm, or 600
nm thermal SiO2 on n-type Si, 0.005 Ω cm, Nova Electronic
Materials) and baked at 180 °C for 5 min and at 115 °C for 1 min,
respectively. The photoresist was patterned by photo-lithography
with a Maskless aligner (MLA150) and developed (MF-CD-26, MicroChem
Corp.) for 30 s. Following this photolithography process, a
60-nm-thick Ni sacrificial layer was deposited by thermal
evaporation (Sharon Vacuum Co.), followed by a liftoff step
(Remover PG, MicroChem Corp.) (Supplementary Fig. 1a). The size of
the Ni sacrificial layer was designed to accommodate the size of
the U-NWFET probe: 30 μm × 100 μm for single U-NWFET probes
(Supplementary Fig. 1h(i)) or 90 μm × 100 μm for up to four
U-NWFETs probes per bend-up probe arm (Supplementary Fig.
1h(ii)).
(2) The photolithography process in step 1 was repeated to
define an 80-μm-long bottom region for sputter deposition of a 60
nm Si3N4 passivation layer (Orion 3 Sputtering Systems, AJA
International). The main body of the Si3N4 passivation layer (75 μm
long) was deposited on the Ni sacrificial layer with 5 μm Si3N4
extending outside of the sacrificial region (Supplementary Fig.
1b).
(3) LOR 1A (Microchem) and diluted S1805 (S1805: Thinner-P = 1:2
(vol:vol)) were spin-coated and baked at 180 °C for 5 min and at
115 °C for 1 min, respectively. The photolithography process in
step 1 was repeated to define arrays of trenches with shapes and
ROCs as described in the main text (Sup-plementary Fig. 1c).
(4) The shape-controlled deterministic nanowire assembly was
used to align disordered straight nanowires into U-shaped arrays as
described previ-ously21 (Supplementary Fig. 1d). Briefly, a wafer
with an array of trenches was mounted onto a
micromanipulator-controlled movable stage, covered with mineral oil
(viscosity v ≈ 70 mPa s, #330760, Sigma-Aldrich) as the lubricant,
and then the nanowire growth substrate was brought into contact
with the target substrate with controlled contact pressure. The
target substrate was moved at a constant velocity of ~5 mm min–1
with respect to the fixed nanow-ire growth substrate; the growth
substrate was then removed and the target substrate rinsed with
octane (98%, Sigma-Aldrich) to remove the lubricant. Estimations of
the U-shaped nanowire strain were calculated and are shown in
Supplementary Table 2.
(5) Al2O3 was deposited directly after the nanowire assembly by
atomic layer deposition (S200, Cambridge NanoTech) with 1 cycle
(1.4 Å) at 80 °C to fix the U-shaped nanowires on the bottom
passivation layer and then all photoresist was removed in Remover
PG (Supplementary Fig. 1e).
(6) Step 1 was repeated to simultaneously pattern electrical
interconnects to the U-NWFET as well as connects to the large pads
used as the input/output (I/O) region. Native oxide on the nanowire
was etched with a buffered oxide etch (BOE, 7:1, Microchem) for 10
s before thermal deposition of asym-metrically strained metal
Cr/Au/Cr (1.5/60/60 nm). The strained metal leads the U-NWFET probe
to bend off the wafer surface following etching of the sacrificial
layer, like that described in previous work21.
(7) Step 2 was repeated to deposit 60 nm of Si3N4 as electrical
passivation over exposed metal features except for the I/O pad
region (Fig. 2b and Supplementary Fig. 1f).
(8) Electron-beam lithography (EBL) or photolithography was used
to define the Ni diffusion region with shape and position as
described in the main text. Specifically, EBL was used for U-NWFET
probes with ~50 nm (Fig. 2c) and ~500 nm (Supplementary Fig. 2c)
channel length. For the EBL process, copolymer MMA (EL6, Microchem)
and polymethyl methacrylate (PMMA, 950-C2, Microchem) were
spin-coated and baked at 180 °C for 5 min, sequentially. The
resists were then patterned with an EBL system (ELS-F125,
Elionix) and developed (MIBK/IPA 1:1, MicroChem Corp.) for 60 s.
For U-NWFET probe with ~2,000 nm channel length (Supplementary Fig.
2d), the same photolithography process in step 1 could be used to
define regions for Ni deposition. Native oxide on the nanowire was
removed by BOE for 10 s before deposition of 20 nm Ni via thermal
evaporation. After liftoff, the chip was annealed using a Rapid
Thermal Processor (RTP, 600xp, Modular Process Technology) in
forming gas (H2:N2 10:90) at 350 °C for 5 min to transform the Si
nanowire segments underneath and adjacent to the Ni diffusion layer
to nickel silicide22, thereby generating a localized sensing
element (Supplemen-tary Fig. 1g).
(9) Polydimethylsiloxane (PDMS) was prepared by first pouring
Sylgard 184 (Dow Corning) elastomer (mixed in a 10:1 ratio of base
to curing agent) into a Petri dish, and then curing overnight at 55
°C in a convection oven. A PDMS chamber with ~20 × 30 mm2 opening
and ~0.5 cm sidewalls was cut from the cured PDMS and mounted
around the device region using Kwik-Sil silicone adhesive (World
Precision Instruments). A printed circuit board (PCB, UXCell)
connector was then mounted adjacent to the I/O region of the
devices and wire-bonded to the U-NWFET probe I/O pads
(Supplementary Fig. 5a). Probes were kept in a Dry-Keeper
desiccator cabinet (H-B Instru-ment-Bel-Art). Before electrical
characterizations and/or electrophysiological measurements, the Ni
sacrificial layers and remaining Ni from the diffusion layer were
removed in nickel etchant (Nickel Etchant TFB, Transense) for 3–5
min, which allowed release of these devices into a 3D bend-up
structure (Fig. 2d and Supplementary Fig. 1h). Following release,
the devices were rinsed in DI water 5–10 times for 20 s each.
Device characterization. Overview optical images of the
measurement set-up and U-NWFET probe chip to instrument I/O area
were acquired with an SLR digital camera (Canon), and
higher-resolution bright-field optical images of individual U-NWFET
probes and probe arrays were acquired by an Olympus BX50WI system
with Andor Luca electron-multiplying charge-coupled device camera.
High-resolution SEM images of nanowires, including intermediate
fabrication steps, were acquired using a Zeiss Ultra Plus field
emission SEM (Carl Zeiss). A BSE detector was used to obtain
high-resolution composition-sensitive maps based on the electron
elastic scattering difference of atomic number on the sample.
U-NWFETs fabricated for characterization did not have a Ni
sacrificial layer to improve contrast during SEM imaging. The BSE
images show the silicon and nickel silicide segments on U-shaped
nanowires: the bright region indicates nickel/nickel silicide and
the dark region indicates p-type Si.
For electrical characterization, one arm of the U-NWFET was
considered as the source, and the other arm is considered as the
drain. Voltage Vds was applied between the source and drain of the
U-NWFET, and the resulting current, Ids, was measured. The
electrical conductance (Ids/Vds) of the U-NWFET devices was
measured in the dry state by sweeping Vds between −1 and 1 V and
measuring Ids using a homemade battery-powered 16-channel current
preamplifier with bandwidth of 6 kHz, which amplified the current
signal for recording using a 16-channel analog-to-digital converter
(Axon Digidata 1440A, Molecular Devices) controlled by pCLAMP 10.7
software (Molecular Devices). The Ids–Vds data were recorded in an
air/dry state.
Surface functionalization of U-NWFET probes. Phospholipid
vesicles were prepared for use in functionalized U-NWFET probes in
the following manner, similar to previous papers15,16. (1)
1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC, Avanti Polar
Lipids) was suspended in chloroform (anhydrous, >99%,
Sigma-Aldrich) to a concentration of 20 mg ml−1 and mixed with 1%
mass of
1-myristoyl-2-[12-[(7-nitro-2-1,3-benzoxadiazol-4-yl)amino]dodecanoyl]-sn-glycero-3-phosphocholine
(NBD-lipid, Avanti Polar Lipids). (2) The solution of
DMPC/NBD-lipid was then placed into a vacuum desiccator for at
least 6 h to evaporate off the chloroform. (3) The resulting powder
was resuspended in phosphate buffered saline (1× PBS, HyClone) to a
concentration of 1 mg ml−1 and the lipid solution was placed in a
water bath at 37 °C for at least 2 h with periodic agitation using
a vortex mixer (30 s every 20 min, Maxi Mix II,
Barnstead/Thermolyne Corp.) to ensure full rehydration. (4) The
resulting lipid solution was sonicated using a tip sonicator (25%
amplitude, 10 s/15 s pulse on/off, Branson Ultrasonics Sonifier
S-450l, Branson Ultrasonics) at ~37 °C for 2 h. (5) Following
sonication, the lipid solution was sterile filtered (0.2 µm
Acrodisc syringe filter, PN 4192, Pall Corp.) and used within 1 h
of preparation.
Immediately before measurements, U-NWFET probe arrays with a
mounted PDMS chamber (Supplementary Fig. 5b) were incubated for 2 h
in 1.5 ml of the prepared lipid vesicle solution to allow
functionalization of U-NWFET as reported previously for other
nanowire devices15,16. Following incubation, the U-NWFET probe
arrays were rinsed in Tyrode’s solution (in mM: NaCl 155, KCl 3.5,
MgCl2 1, CaCl2 1.5, HEPES 10, d-glucose 10, pH 7.4 for DRG neurons,
or NaCl 138, KCl 4, CaCl2 2, MgCl2 1, Na2HPO4 0.33, HEPES 10,
glucose 10, pH 7.4 for HiPSC-CMs, all chemicals in Tyrode’s
solution were purchased from Sigma-Aldrich) 5–10 times for 20 s, ~3
ml each.
Device characterization in Tyrode’s solution. Following
phospholipid modification, electrical measurements were carried out
in Tyrode’s solution.
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Articles Nature NaNotechNologyThe electrical conductance of the
U-NWFETs was continuously measured by recording the drain–source
current (Ids) at a fixed source–drain d.c. bias between 0.1 and 0.2
V by the electronic measurement set-up mentioned above. The
sensitivities (transconductance) were then obtained by sweeping an
Ag/AgCl reference electrode (2.0 × 4.0 mm, E-201, Warner
Instruments) between −100 mV and 100 mV and measuring the
corresponding linear change in U-NWFET conductance. The measured
average (in 10 samples) conductance of U-NWFETs for channel lengths
of ~50 nm, ~500 nm and ~2,000 nm are 3.3 ± 0.6, 0.7 ± 0.2 and 0.3 ±
0.1 μS, with average sensitivities of 5.4 ± 1.3, 2.3 ± 0.7 and 0.9
± 0.3 μS V−1 respectively. An inverse relationship exists between
conductance, and consequently transconductance, and channel length,
as expected from the relationship: (G = σA/L), where G is the
channel conductance, σ is the electrical conductivity, A is the
cross-sectional area of the wire and L is the channel length39.
To estimate the noise level of the U-NWFETs devices, the
conductance of the 10 devices for each channel length was measured
using the Ag/AgCl reference electrode to fix the solution voltage
at 0 for ~5 s. The standard deviation of the measured conductance
was used to obtain the noise for each device in μS. Then, the
transconductance of each device was used to convert the measured
noise in μS into a value in mV, and the resulting number was
multiplied by 3 to estimate the limit of detection as per
convention. Averaging the 10 values for the limit of detection (in
mV) for each channel length resulted in noise levels of 0.90 ±
0.60, 1.2 ± 0.9 and 1.9 ± 0.9 mV for the ~50, 500 and 2,000 nm
devices, respectively.
Preparation of flexible cell culture substrates. A master mould
for the culture substrate was first prepared by spin-coating SU-8
2000.5 (Microchem) onto a Si wafer and patterning repeating
3-μm-wide lines with 3 μm spacing using photolithography. After
patterning, the master mould was hard baked on a hot plate at 180
°C for 2 h, and then silanized with
tridecafluoro-1,1,2,2-tetrahydrooctyl-1-trichlorosilane
(Sigma-Aldrich) for 2 h in a vacuum desiccator, to enhance release
of the PDMS template from the master mould40.
Flexible PDMS cell culture substrates were prepared by
spin-coating Sylgard 184 elastomer mixed in a 10:1 ratio of base to
curing agent onto the master mould at 250 r.p.m. for 1 min. The
PDMS on the master mould was then cured in a convection oven set to
180 °C for 2 h, resulting in a thickness of ~220 μm, and cut into
pieces (~10 × 10 mm2) for cell culture. Before cell culture, the
PDMS substrates were autoclaved at 125 °C for 1 h, treated by O2
plasma (100 W, 2 min, 50 s.c.c.m. O2) and then washed in a 75%
(vol/vol) solution of ethanol (200 proof, KOPTEC)/water for 1
h.
For DRG neuron culture, the PDMS was first functionalized with
40 µg ml−1 poly-d-lysine (molecular weight of >300,000 g mol−1,
Sigma-Aldrich) in DI water for 1 h at room temperature. After
poly-d-lysine functionalization, the PDMS was washed twice in DI
water for 30 s each and air dried, and then functionalized with 20
µg ml−1 laminin (Thermo Fisher Scientific) in Leibovitz’s L-15
(Thermo Fisher Scientific) for 1 h at room temperature. Laminin
solution was removed immediately before the cell suspension was
plated on the PDMS.
For HiPSC-CM culture, the PDMS was functionalized sequentially
with (1) 1% (3-aminopropyl)triethoxysilane (Sigma-Aldrich) in a 95%
(vol/vol) solution of ethanol/DI water for 20 min at room
temperature, followed by washing three times in ethanol for 30 s
each, and three times in DI water for 30 s each; (2) 2.5% (vol/vol)
glutaraldehyde (grade I, 50% in H2O, Sigma-Aldrich)/water for 1 h
at room temperature, followed by washing three times in DI water
for 30 s each; (3) Geltrex matrix (Thermo Fisher Scientific) at 37
°C for ~8 h. The Geltrex solution was removed immediately before
the cell suspension was plated onto the PDMS.
Cell culture. Dissociated DRG cells were prepared as described
previously35 and cultured in the CO2 incubator overnight before
use. Cells that can spontaneously fire (Supplementary Fig. 8) were
selected for recording. HiPSC-CMs were cultured as described in the
NCardia online protocol41. Cryogenically frozen
Cor.4U HiPSC-CM vials (Cor.4U > 250k cells, Ncardia Group)
were thawed in a 37 °C water bath, and 0.5 ml of proprietary Cor.4U
cell medium (Ncardia Group) preheated to 37 °C was added to the
vial. The cell solution was then homogenized by gentle aspiration
and seeded at 75,000 cells per cm2 to achieve confluency onto the
prepared PDMS substrates. Immediately following cell seeding, the
cell culture was left at room temperature for 20 min to allow the
solution to settle and ensure an even distribution of cells. The
cells were then cultured in a 5% CO2, 37 °C incubator and the
Cor.4U cell medium was changed 6 h following plating. Subsequently,
the medium was changed every day and the cells were used within 2
weeks following seeding, once a uniformly contracting layer was
observed.
Electrophysiological recording with U-NWFET. The Ag/AgCl
reference electrode was used to fix the extracellular Tyrode’s
solution voltage to 0 V for cell measurements. A PDMS sheet with
cultured DRG neurons or HiPSC-CMs was fixed upside down onto a
homebuilt vacuum wand mounted on a 40 nm step resolution x–y–z
micromanipulator (MP-285, Shutter Instruments) connected to a
micromanipulator controller (MPC-200/ROE-200, Sutter Instruments)
to position the cells over and bring the cells into contact with
the U-NWFETs (Supplementary Fig. 5c). The Tyrode’s solution was
maintained at room temperature for the DRG neuron experiments and
at ~37 °C for the HiPSC-CM experiments. For longer (>3 min)
HiPSC-CM intracellular recording (Supplementary Fig. 9b,d), high
pass filters were set to 0.4 Hz, similar to the approach used by
other groups12,42,43.
Patch-clamp recording. Patch-clamp recording was performed at
room temperature using a Multiclamp 700B amplifier (Molecular
Devices) and a Digidata 1440A Digitizer Acquisition System,
controlled by pCLAMP 10.7 software (Molecular Devices).
Micropipettes were prepared using a micropipette puller (P-97,
Sutter Instruments) and the pipette tip resistance ranged between 5
and 10 MΩ. DRG neurons were cultured on a glass coverslip with the
same modification as PDMS. Recording from DRG neurons was carried
out in Tyrode’s solution. The micropipettes were filled with an
internal solution consisting of (in mM): potassium l-aspartate 140,
NaCl 13.5, MgCl2 1.8, ethylene
glycol-bis(2-aminoethylether)-N,N,N′,N′-tetraacetic acid (EGTA)
0.09, HEPES 9, phosphocreatine di(tris) salt 14, adenosine
5′-triphosphate (ATP) magnesium salt 4, guanosine 5′-triphosphate
(GTP) tris buffered 0.3, pH 7.2 adjusted with KOH6. All chemicals
in the internal solution were purchased from Sigma-Aldrich, except
GTP tris buffer, which was purchased from Thermo Fisher.
Data availabilityThe data that support the findings of this
study are available from the corresponding author upon reasonable
request.
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